Temperature-producing mechanism and controlling means therefor



. E A- BL FB'ENJEBQ TEMPERATURE PRODUCINGMEC HANlSM'AND CONTROLLING MEANS THEREFOR.

APPLICATION FILED NOV171 I919.

9 SHEETS-SHEET 1.

Patented May 24,1921.

' WITNESSES I I v a INVENNTOR. I

ATTORNEY A. B. FRENIER.

TEMPERATURE PRODUCINGMECHANISM AND CONTROLLING MEANS THEREFOR.

APPL1CATION FILED NOV 17,1919. 1,379,008.

Patented May 24, 1921.

9 SHEETSSHEET 2- 7?Z272f077' aw; 679 W g A. B. FRENIER.

TEMPERATURE PRODUCING MECHANISM AND CONTROLLING MEANS THEREFOR.

APPLICATION HLED NOV 17. 1919.

s I I 7? I A. B. FRENIER. TEMPERATURE PRODUCING MECHANISM AND CONTROLLING MEANS THEREFOR.

APPLICATION FILED NOV I7, 1919.

Patented May 24, 1921.

9 SHEETSSHEET 4.

mm NH? A. B. FRENI'ER.

TEMPERATURE PRODUCING MECHANISM AND CONTROELING MEANSIHEREFOR. ICATIONY FILED'NOV, 17, I919.

"1,879,008. I Patented May 24, 1921.

9 SHEETSSHEET 5.

A. B. FRENIER.

TEMPERATURE PRODUCINGMECHANISM AND CONTROLLING MEANS THEREFOR.

APPLICATION FILED N0v..17,l919.

1,879,008, 'Patnted May24,1921.

9 SHEETSSHEET 6.

A. B. FRENIER.

TEMPERATURE PRODUCING MECHANISM AND CONTROLLING MEANS THEREFOR.

APPLICATION FILED Nov, 11, 1919.

Patented May 24, 1921.

9 SHEETSSHEET 7- I I 7? M67710 71' %?77693. j M I (777777-777 A. B. FRENIER. I v TEMPERATURE PRODUCING MECHANISM AN DCONTROLLING MEANS THEREFOR.

APPLICATION 'HLED NOV. 17, 1919.

a T E 4%. 24 8 Wm MM d 9 m n e. t a P 15:. I ll PIFIIIHI l.

.PIIIIIIIJ A. B. FRENIER.

TEMPERATURE PRODUCING MECHANISM AND CONTROLLING MEANS THEREFOR.

I APPLICATION FILED NOV 1 7. I919.

1 ,379,008. Patented May 24, 1921.

9 SHEETS-SHEET um'rso srAri-zs .mm'r B. lamina or cmcacdmnrora 'rEurnna'runn-rnonucme monument AND conrnoume mamas'rimmnron.

To all whom it may concern:

Be it known that'I, ALBERT a citizen of the'United States of America,

and resident of Chicago, Cook county, Illinois, have invented a certain new and useful Improvement in Temperature Producing Mechanism'and Controlling Means Therefor, of which the following is a specification.

My invention relates to the art of burning liquid fuel as a substitute for solid fuel in connection with furnaces generally, and more especiall in connection-with steam or hot water boi ers or hot air furnaces com monl used for heating homes or other buildings.

In the burning of liquid-fuel, especially non-volatile or heavy hydrocarbons, the fuel is either va orized-that is, converted from its 1i uid orm into a gas by the application o heat and the gas so formed is burned in various forms of burners of the Bunsen type, resulting in a shortblue flame of conslderable intensity; or ,it is atomized or sprayed and when mixed with the proper proportion of air is capable of practically complete combustion and ives orth an intensely white -fl'ame of voluminous-proportion. Atomizing the fuel is usually brought about either by subjecting the liquid to high pressure,,f0rcing it through a jet or nozzle provided with mi- ;nute outlets, or it is atomized: through the I agency of high pressure air or steam. This latter method isusually resorted to in con -nectioxi with forging furnaces or steam ing method is generally resorted to, but as boiler plants of factolmis where ractically unlimited space for proper? com ustion is available. Where the burning of liquid fuel is applied to devices in which the available spacefor combustion is exceedingly limited or circumscribed, the vaporizing or gasifythe fuel must be subjected to high pressure in all vaporizing devices, the element of danger due to the pressure on the fuel lines, the requiring of much machinery in the way of oil pumps and air compressors, together with the constantfouling and clogging up of the gasifying tubes,-renders the vapor izing plan unfit for domestic use.

The principal object of my invention is in the utilization of simple dependable and;

B. Fnnnmn,

arge

Specification o! Letters Patent. I Patented 'DIay 24, 1921- I Application iiled November 17, 1919. Serial No. 888,483. I

thoroughly automatic means for atomizing the fuel, whereby all the danger incident to 55 gas fying and the use of much complicated mechanism is avoided.

To universally employ a. liquid fuel would require either the abandonment of the almost universally used coal-burning furnace, or the provision of means by which to change the coal-burning furnace into a liquidfuel-burning furnace.

One of the objects of my invention conslsts in the provision of simple and economical means whereby the ordinary heating furnace designed to burn coal or other solid 2 fuel may be transformed into a heating'furnace, desi ned to safely and properly burn liquid fue such as kerosene or other nonvolatile hydrocarbons.

By my invention the-coal-burnin furnace, in its transformation into a liqu d-fuel burner, need notbe physically altered in amanner or to such a degree as to impair its function in the concentration, regulation and utilization of the heat generated; and

the restoration of the furnace as a coalburner may be accomplished by simply removing the liquid fuel burning apparatus.

Another object of my invention is the roviding of means whereby combustion o the liquid fuel when applied to a coal-burning furnace is completed and; maintained independently of the combustion chamber or fire-box of such transformed furnace, thus always insuring, through complete combustion, the highest efliciency without regard to the efiiciency or inefliciency of the original fire-box. the flaming combustible being confined in a manner to prevent direct contact thereof against the furnace walls or other rying it into effect, and will describe the invention in detail in connection with such apparatus.

In the drawings- Figure 1 is a diagrammatic view of the device as applied to an ordinary steam or hot water boller as commonly used for heatin homes. I

ig. 2 is an end elevation of a complete unit ready for installation into a boiler or i Fig. 8.

Figs. 10, 11, 12 and 13 are, respectively,

sectional views taken on lines 10-1(), 11-11,

1212 and 13-13 of Fig. 9.

Fig. 14 is a top plan view of the heat regulator, showing the receptacle on the forward side to recelve the electric switch and the connection to the pilot light valve on the rear side.

Figs. 15. and 16 are detail sectional views of the electric switch.

Fig. 17 is a front elevation of the heat regulator showing in dotted lines the electromagnetic means for controlling the switch shaft.

Fig. 18 is an end elevation of Fig. 14

partly broken away to show the electromagnetic controlling means, and indicating in dotted lines spring-controlled means for operating the shaft.

' Fig. 19 is a detail sectional view of the pilot light valve.

Fig. 20 is a circuit diagram of the electric controlling circuits.

The combustion chamber 1, (see Fi 2-5) consisting of a heavy metal box-1' e structure provided with the inwardly extending. flanges 1 at its upper edge, and the splitter 1 at one end, is supported upon 'the ash pit floor of the furnace by the adjustable stand 2 through the medium of the lug 1 cast integral with the combustion chamber. Connected to thecombustion chamber by the air pipe 3 is the blower housing 4 p which contains the fan 5 driven by the motor stand 7 and the In 6, which may be cast integral with the blower housing or otherwise suitably secured thereto. The blower housing and motor are supported upon the basement floor outside of the furnace by the adjustable 8, which may be cast integral with the b ower housing 4.

Entering into, and secured to the side of,

the combustion chamber 1, opposite the splitter 1", is the air venturi 9, and secured to the air venturi by the same cap-screws 9 by which it is fastened to the combustion chamber, but separated therefrom by the insulatingrgasket 9", is the fuel nozzle retainer 10. o the free end of the fuel nozzle retainer 10, the air, pipe 3 is inserted and is of venturi shape and provided with the flange 11 at one end and the threaded portion 11 at the other end. Exteriorly of, and concentric with, its venturi throat is the channel 11 The fuel nozzle is securely and snugl held within the cylindrical portion 11 0 the holder 11 with an airtight fit by the locking nut 11. The air-tight fit is essential to the formation of a vacuum in the chamber formed by the channel 11. Leading from this chamber to the throat of the fuel nozzle venturi are the ports 11. Also communicating with this chamber is the passage 11 in the holder 11 which connects with the fuel pipe 12.

Pendant from the blower housing 4 (see Figs. 2 and 4), as by the bracket 12 is a float chamber 12 of conventional form, consisting'of the usual needle valve actuated by a brass ball or cork float, functioning to open or close a port in the bottom of the chamber through which the liquid fuel is admitted into the float chamber. It is connected to the source of supply by the pipe line 12 in which line is located the emergency valve 12, hereinafter more fully referred to, the outlet side of the float chamber being connected to the fuel nozzle 11 by the fuel pipe 12 at the threaded inlet 12 of the fuel nozzle. Connection is made with the fuel storage tanks A (Fig. 1) at 12. The tanks A are elevated sufliciently to cause the fuel to. flow to the float chamber by gravity. The float is so adjusted as to maintain the level of the fuel at about the center of height of the float chamber. When the apparatus is in operation, the fuel must be lifted by 'aspiratlon from this level to the fuel nozzle, in practice, a distance of three or four inches.

Located on the basement. wall or other support adjacent the boiler is the heat regulator 13, which may be of the ordinary spring motor type or may be electrically operated. The one shown (see Figs. 17 and 18) is provided with the usual clock works, indicated in dotted lines in Fig. 18, o erated by a heavyspring to be wound in t e usual manner by a key or crank. On the 16, as shown.

main. Shaft s, which is dperated by the clocklspring, the cam 16' is secured. This camis'provided with the positely dis-f posed notches 516. The sha 13 is prevented from' rotating whenthe' s ring motor is wound b the engagement 0 one of the notches wit the end ofthe dog 16", which is integral with the counter-weighted lever 16? pivotally su ported b the standards y no end 0 the lever 16" is provided with the counter-Wei ht 16 while the opposite end is' supplied with the armature plate 16 so posltioned relative to the electromagnet 16" as to be attracted and actuated thereby. This electromagnet is controlled by a thermostat located in the living-room to be heated, as is common ractice in connection with coal-fired heat-.

ing plants, as indicated in Fig. 20.

- he pilot light 14, su plied from the city gas line, is located in t e floor of the comustion chamber 1 directly in front of, and slightly beneath the end of, the air venturi 9. It is connected by the pipe 14" (Fig; 1)

to the gas valve 14" located in the rear of g the heat regulator 13, which valve is operatively connected by the self-adjusting cou pling 14* (see Fig. 14) to the shaft 13; connection 1s also made from the valve 14" to Dthe city gas line. This valve (see Fig. 19) is of the usual plug type consisting of the body portion 14, the plug valve and stem 14, the packing gland 14 and the gland nut 14. The bottom portion of the valve body is provided with the port 14 functioning as a by-pass, permitting the ,pilot light to burn continuously in a low flame. The by-pass is provided with the adjusting screw 14 whereby the size of the low burning pilot flame may be regulated.

The electricswitch mechanism controlling the circuit to the blower motor is located in the condulet 15. which may be made integral with or otherwise suitably secured to the housing of the heat regulator 13. It is provided with the cover plate and is located relative to the heat regulator at a point to receive the end of the shaft 13" through its center. This switch (see Figs.

' 15-17) consists of a practically crescentshaped insulating block 15" properly secured to the bottom of the condulet 15 and the spring regulator housing by the screws 15. Secured to the block 15", and properly insulated from the condulet, are the terminals 15. Rigidly secured to one of the terminals and to the face of the block 15" lS- the sector-shaped contact member 15. Rigidly secured to the end of the shaft 13 by the set-screw 15' and capable of rotation with the shaft is the circular spool-like insulating block.15 Secured to the outer end of this block by the screws 15 is the washerlike metallic member 15, with its periphery extending considerably beyond that of the spool forming an overhanging ledge. Extending beyond the periphery of the washer 15 and formed integrally thereof is the rearwardly extending contact finger or brush 15". The rotating block- 15 is so positioned relative to the stationary block 15" that the free end of the finger 15" will travel in the splane of and contact with the the position shown, clear of the sector 15",v

opening the circuit.

As a means of stopping the entire mechanism and closing a valve in the fuel line from the storage tanks to the burner, in the event. the city gas should be shut ofi' temporarily, or the .gas'pressure reduced (through unusual consumption throughout the city at certain hours or otherwise) to a point where the pilot light would become extinguished and there would'be no resultant flame to ignite the fuel when the thermostat functioned causing fuel to be fed into the furnace, a combined safety switch and'valveoperating device 17 is provided, suitably secured to the blower housing 4 as by. the 111g 17. In the lower portion of the switch housing 17 (see Figs. 8-13) the spring-actuated member 17" is journaled for free and easy rotation inthe bearing 17, which is securely fastened to the side of the housing by the screws 17. Secured to the outer end of the member 17", as by the pin 17, is the arm 17 The innerend of this member 17" is of reduced diameter and piloted into the switch member 18. Extending from and formed integral with the member 17" is the arm 17*, which is connected by the half-circle section 17" to the tension spring 17, which in turn is adjustably secured to the housing 17 by the adjusting screw. 17, whereby the desired tension can be put into the spring. The inner end of the member 18 is slotted at 18 to receive the flattened portion 17 of the member 17", (as shown in Figs. 12-12 It will be observed that this'flattened portion 17 is of less width than the slot 18, and as,

.the en gement of the flattened portion 17 with t e slot 18 forms' the only means of transmitting rotary movement to the member 18 by the member 17", the member 17" is capable of a limited initial rotary movement without imparting movement to the member 18, thus forming a 'lost motion &

connection between these two members for purposes that will more fully hereinafter apear. P Formed inte ral with the member 18 is the arm 18 (Figs. 9-11) which, with the insulating connectors '18 and the metallic member 18, forms the blade of a knife switch arranged to engage with the stationary contacts 18 secured to the insulat- 10 ing block 18 by the screws 18 The block 18 in turn is suitably secured to the housing 17 as by the screws 18". The outer portion of the member 18 is rotatively journaled in the bearing 18 and is provided with the flattened end 18 extending out beyond the switch housing 17, where it is made to engage the stem 19 of the fuel valve 12 by the universal coupling 19. This valve 12 is of the usual plug type provided with a 20 closed body and packing gland and nut to guard against possible leaks.

To the arm 17 which is pinned to the member 17*, is suspended the drain or overflow receptacle 20 (see Fig. 2), through the medium of the bail 20. Leading from the combustion chamber 1 is the drain pipe 20 (see Figs. 1, 3 and 4). This drain pipe is screwed into the combustion chamber near the floor line thereof and to one side of the air venturi 9, and leads to the drain receptacle 20. It is provided near its free end with the U-bend functioning as a trap to prevent the possible escape of prodnets of combustion. The operation of the entire mechanism is as follows :-'-After suitable connections have been made with the gas main and fuel supply, the pilot light 14 is ignited and burns with a low flame, due to the fact thatthe e0 valve 14 is at this time closed, the as passing through the by-pass 14'. en the thermostat B operates, owing to a drop in room temperature, to close the circuit through the magnet 16 this magnet oper- 4 ates to withdraw the awl 16 from the notch 16 in the cam 16, t us releasing this cam gand permitting the clock-workmechanism to rotate the shaft 13 a one-half revolution,'

When'the pilot li ht is burning with a low flame and the fue' supply shut oif,then the brush 15 is out of contact with the segment 15, .and, therefore, the circuit for the.

blower-motor is broken. As soon as the shaft 13 starts to rotate in the man- 5 ner above described, the plug 14 of the gas valve 14 starts to rotate so as to open the main passageway to the pilot light, thus ermitting this light to increase in size and burn with a full flame. As the shaft continues to rotate, the brush 15 engages the end of the contact segment 15, thus closing v the circuit for the'blower motor 6.

' The rush of air from the pipe 3 extending fromthe blower tothe combustion chamber through the fuel nozzle, produces a vacuum in the chamber 11 drawing up or aspirating the liquid fuel through the passage 11" of the holder 11, atomizing it into a fine spray and blowing it into the combustion chamber mixed with the proper amount of air to support complete combustion. It will thus be observed that a portion of the large volume of low 'ressure air from the air pipe 3 passes throug the fuel nozzle functioning principally as an aspirating and atomlzing agency, and the remainder of the air passes. around outside of the fuel nozzle into the air venturi 9, speeded u and brought into intimate contact and t orou hly mixed with the sprayed fuel at the V anturi throat 9, thus producing a'combustible sprayed vapor which is blown into the combustion chamber and there ignited by the pilot light.

The flaming combustible is projected b the blower with that degree of force whic will overcome the natural tendency of the flame to rise, and the reactive force of the side walls-and instanding flange or divider is utilized to continuously turn the flame back u 11 itself until combustion is complate. ince this vertical bafiie or divider is directly in the path of the stream of flame from the mixture forming mechanism, the flame is divided thereby and turned laterally in two directions with the result that a double vortex of horizontally moving flame is produced. Each of the divisions of flame is projected along the walls of the chamber and at the curved corners is repeatedly turned back into the vortex. 'Any further tendency of the flame, if any there be, to rise out of the combustion chamber-is ofiset by the reactive forced the continuous baflle flan e surroundin the upper edge of the com ustion cham er. When installed in the fire-box of the ordinary house heating furnace or boiler, this combustion chamber not only functions to prevent theflaming combustible contacting the walls of the firebox," but what is of greater importance it forms a means whereby complete difl'usion of the gasesincident to the proper burning of the fuel is effected prior to combustion rather than subsequent thereto.

It is well understood by those versed in the art that in the burning of fuel, either hard or liquid, complete combustion is at-- tained when the carbon, or combustible mat,-

.ter in the fuel, is burned to form CO gas,

liberating 14,500 B. T. U. per pound of carbon and that incomplete combustion follows when the carbon is burned to form CO as yielding but 4450 B. T. U. per pound of carbon. To burn hard fuel in the ordinary house heating furnace or/ boiler, to form CO gas to the exclusion of CO, requires the constant attention of a skilled fireman-it is in fact a purely laboratory achievement seldom if ever accomplished in actual practice. While the task of producing CO, 'gas to the exclusion of CO is easier of attainment in] structure of the fire-box of the furnace when liquid fuel is'to be substituted for hard fuel and a constant manipulation of the ash pit and stack dampers becomes necessary.

When an atom of carbon is brought in contact with an atom of oxygen at a sufliciently high tem erature, combustion takes place forming -0 gas, and unlessthis CO molecule so formed meets with or is met by another atom o f'oxygen before its temperature has fallen below the ignition point, it will pass off through the smoke stack as CO gas,

carrying with it of the heat units which it is capable of yielding. The lar e voluminous .flame from the burning of iquid fuel by. the atomizing process, as heretofore practised, therefore requires a large, spacious fire-box which must be kept at an exceedingly high temperature to insure that every (3 molecule will combine with that other atom of oxygen necessary to complete com- I bustion. Under these circumstances proper diffusion of the gases takes place subsequent 4 to combustion, if at all, andherein lies the greatest obstacle to complete combustion of liquid fuel, as the constant high temperature of the fire-box and the introduction of the proper amount of oxygen by the admission of air through manipulating dampers requires the constant services of the' skilled attendant.

In projecting the finely divided fuel a mixed with .the proper amount of air into the combustion chamber herein referred to a furnace has been effected, the walls 0 which are walls of white-hot flame wherein every molecule of CO simultaneous with its formation is met by and combines with that other atom of oxy en to the immediate formation of- CO I cult to control in the. combustion of coal or w oil by the methods heretofore practised is here'absent. TheCO molecule and the oxy- 3 gen j U a suflicient time to insure their combination.

are here confined by the swirling action The CO. molecule cannot get away and wander about, as it were, until loss often I p fure'below ignition point-would render I as,

combination fim-possible. 5 p

As the successful burning of liquid fuel by the usual atomizin process as. heretofore practised, resulting in a large mass of flame, can only be acquired by insuring proper diffusion of the gases subsequent to combusv tion, and as this subsequent diffusion de- 60 1 of the fire-box, coupled with expert iligence in the regulation of air. sup ly, the use of mands a constant uniform high tem erature liquid fuel for the heating 0 homes, wherein the demand for temperature .is interm ttent. and the manipulation of the heating e811 impracticable, if not impossible.

he time element so difii-.

lant is .in the hands of the unskilled has owever, by the use of this auxiliary combustion chamber in conjunction with the fire-box of the ordinary house heating furnace, the necessity of maintaining that constant uniformly high temperature of the fire-box. and

this expert diligence in the matter of air regulation to insure proper diffusion. of the gases subsequent to combustion is completely avoided regardless of shape, size, or contour of such fire-box or the intermittent demand for temperature.

As the shaft 13" completes its half revolution, it is brought to a stop by the pawl 16" engaging with the opposite notch 16 in the cam 16, as. the circuit through the magnet 16 was broken .as soon as the finger 16 moved out of contactwith the corresponding lug or post 16. In this position of the parts, indicated in Fig. 17, the'circuit for the blower motor is maintained closed, but the gas valve upon completing the half revolu- :tion has again been turned into position to close the main passageway to the pilot light, and thus the pilot light again reduced to a small flame.

,It is well known to those familiar with the art that a mixture of non-volatile heavy hydrocarbon, such as kerosene, at normal temperature, and air in suflicient quantity to support complete combustion to the exclusion of soot, smoke or odor, is most difii- .cult to ignite. It is non-ignitible by an electric spark re rdless of the temperature of the spark. ven a flame of the proportion of an ordinary pilot light is insuflicient to insure ignition, especially at low temperature. In sub'ecting the fuel. and air. to the action of a enturi tubethe matter of i nition becomes all the more difficult, in act under such conditions and especiall at low atmos heric temperature the electric spark or sma 1 pilot flame utterly fails. This seems to be dueto the fact that the small particles of atomized liquid when subjected to the ac tion of a Venturi tube are traveling at such a high rate of speed they are not in the zone of heat of the s ark or small flame, a sufficient length 0- time whereby their temperature can be raised to the point of i ior more ,of t ese To insure prompt and unfailing i nition of such a mixture from a cold state t e em ployment of a flame of considerable proportions isabsolutely essential, and'this large flame must endure for a roperperiod of time. It cannot be flashe on and of! 'instantl but must persist for several seconds. The arge flame seems necessary so that that propagation of flame is immore particles of the liquid shall be in the zone of heat at one time and for a sufficient period that their temperature shall be raised to the point of ignition. Thus it becomes apparent, in connection with the apparatus herein described, that by expanding the city gas pilot light to a'flame of considerable size, in fact entirely filling the combustion chamber with such flame and by causing same to persist for a considerable predetermined period, in practice about twenty seconds, prompt and unfailing ignition is insured regardless of atmospheric temperature.

It will be observed thatwith the switch in its closed position, as shown, the free end of the brush 15 contacts the sector 15 an appreciable distance from its end, so that upon opening of the circuit by the half revolution of the shaft 13 the circuit remains unbroken until after the shaft has made a partial revolution, and the brush 15 has cleared the end of the sector. So likewise upon completion of this half revolution of the shaft 13 the end of the brush 15 will come to a state of rest at a distance from the lower end of the sector 15 equal to the distance it overlapped the sector with the switch in closed position. By this construction the pilot flame is considerably expanded by the partial opening of the gas valve before the circuit to the blower motor is closed, so that the strong blast of air immediately following the starting of the blower cannot possibly extinguish or blow out the pilot light, as the brush 15 is caused to travel some appreciable distance before it can close the circuit by contacting the sector 15' to start the blower. The gas flame in the meantime has been expanded by the partial opening of the valve to a point entirely past the danger of extinguishment by the blast from the blower. As the blower motor does not come to a dead stop immediately upon breaking of the circuit, but to the contrary, due to the momentum of the rapidly revolving blower fan and motor armature, the blast ofair would be continued for a sufficient period and would be ofa sufiicient magnitude to blow out the low burning pilot flame, the necessity of expanding it both on starting of the blower, as well as when stopping it, becomes apparent.

When the thermostat next responds to a rise in room temperature to again close the circuit for the magnet 16, of the heat regulator switch mechanism, this magnet again operates'to permit the shaft 13 to make a half revolutlon in'the same manner above 60 described. During this operation of the shaft, the pilot light is again increased toa full flame, as heretofore described, and then the circuit for the blower motor is broken by the brush 15*- moving out of en- 65 gagment with the constant sector 15, and

. Havin now described the normal operation of t e apparatus, I will now set forth the operation of the various emergency devices. In the event that the pilot light is not burning when the liquid fuel is supplied to the .combustion chamber, this liquid fuel is then drained from the combustion chamber, through the drain pipe 20 into the receptacle 20. In normal position, with the arms 17, from which the drain receptacle 20 is suspended in its up position, as shown, the arm 17, and the end of the spring sector 17 to which it is attached, will be in a position slightly forward of the vertical diametrical center of the member 17", as shown at X in Fig. 12, and will have rotated said member to a position whereby the knife switch is closed and the fuel valve 12 is opened, the spring 17 functioning at this time to hold the parts in this position. When an inch or two of liquid has accumulated in the receptacle 20, sufficient force will have been supplied to the arm 17- to initiate a rotative movement to the member 17". As stated above, the normal position of the member 17 and the inte ral arm 17 is as shown in Fig. 10,--that is, with the end of the arm to which the sector 17 is secured, slightly forward of the diametrical center of the member 17" and with the 106 -volve it contra-clockwise with the flattened portion 17 of the lost motion connection between 17" and 18 occupying the position as shown by the full lines in Fig. 12. So the only duty or work to be performed by the accumulated liquid in receptacle 20 is to move the arm 17 8 from a position forward of the center line as shown at X, Fig.

12, to a position back of this center line as U0 shown at Y, it having at the, same time rotated the flattened portion 17 to the positionshown by the'dotted lines in Fig. 12. The instant arm 17 F passes to a point back of thecenter line, the direction of pull 'of the 11 spring, aided by the weight of the liquid in the receptacle, is reversed, imparting a clockwise motion to member 18, throwing the knife switch open with a snap, closing down the blower motor, and closin the fuel line, the entire devlce remaining in this shut down condition until the .receptacle is emptied and arm 17 raised, restoring all parts to normal position.

To meet the contingency of the rather 1'0 V throug failure of the needle valve, due to possible lodgment of dirt or foreign matter 13 valve 12 in 120.

on thevalve seat, the drain leading from the float chamber to the same receptacle 20 is provided. This drain, if the float chamber becomes flooded, will conduct the fuel into the receptacle 20, which will immediately function, as above described, and close the fuel valve 12 which, as stated, is located between the supply tanks and the float chamber.

' It is often desirable that the burner mechanism be controlled by boiler conditions (pressure in connection with the steam boiler, and temperature in connection with the hot water boiler), rather 'than room temperature, as it frequently happens in connection with a very cold house on a cold morning that steam pressure or requisite water temperature will be reached long before the requisite room temperature. In order to meet with this contingenciv, I provide a supplemental switch 1 20), which is actuated by a sylphon device controlled in the usual manner by the pressure in a steam boiler or temperature in a hot water boiler such as F. The operation of this switch will be readily miderstood by reference. to this diagrammatic view in which I have indicated the various electrical controlling circuits. Referring to this diagram, 1t Wlll be seen that one of the termi-' nals of the magnet 16, which controls the heat-regulator-operated switch, is connected to one pole of the battery C, while the other is connected to the brush 16 carried by the .cam 16. The lug or post 16 with which this brush engages, is connected by means of the conductor 26 to one terminal of the thermostat 13,; while the other post 16 is connected by means of the conductor 27 to the opposite terminal of the terminal thermostat. The movable member of the thermostat is connected by means of the conductor 25 to the up er contact of the he middle contact means of the conductor28- to the other terminal of the battery C. The lower contact of this switch is. connected to the conductor 27 which is connected to the lug or post 16, thus lacing one side of the thermostat B and are switch D in parallel. When the three point switch D.

. sylphon E expands, due to the increased pressure in the boiler,

the contact member 24, which is connected to the sylphon by the connecting member 23, is moved down into the position shown, thus temporarily cutting out of circuit the room thermostat. and placing the actuating circuits under the control of the sylphon E. This control of the heat regulator will be maintained until the-pressure at the boilerhas subsided, when the contact member 24 will returned to normalposition, thus again cutting" 1n circuit the thermostat and cutting outthe sylphon, and in this manner again throwing the control of the fire back on the room thermostat.

the city line,.whi-le the-other .side is connected to the opposite side of said source by conductor 22 which passes through the heat-regulator-operated switch 15 and the" safety switch 18.

It will thus be seen that I have devised a veryeificient mechanism which can be very readily and easily substituted for the solid fuel burners now being employed, in which most eflicient results are obtained and in which the control is entirely automatic, and in which very effective. emergency devices are provided to meet all and any abnormal conditions that may'arise." While I-have illustrated and described one "particular embodiment of my invention, it will be understood that I do not wish to'be limited to the exact construction shown and.

described, but that various changes and modificatlons may be made without depart I ing from the splrit and intent of my in-.

fuel atomizer for spraying liquid fuel into 'fire-boxfand independent thereof, a liquid said combustion chamber, and means for igniting said fuel, said combustion. chainber operating to substantially confine said flame within said chamber and to 'prevent same from .impingingagainst the walls of said fire-box.

2. In combination, a heati .device including a fire-box, a liquid elburnin'g combustion chamber capable of ready insertion intoand withdrawal from' said firebox, a 1i uid fuel atomizer for. spraying liquid fue into said combustion c amber,

and means for igniting said fuel, said com-' bustion chamber operating to substantially confine said flame within'said chamberand to prevent same from' impingin'g against the walls'of said fire-box.

3. In combination, a heatingl device ineluding a fire-box, a liquid e1- burning combustion chamber mounted within said fire-box and independent thereof, means for spray ing liquid fuel and air in said-combustion chamber, means for igniting said fuel, said combustion chamber operating to confine the sprayed fuel and air within said chamber until the oxygen of the air has united with the combustible of the sprayed fuel in sufiicient quantity to bring. about 7 a comlplete combustion of the fuel.

4. n combination, a heatingI device including a fire-box, a liquid .el burning 1 combustion chamber mounted.within said fire-box and independent thereof, means for spraying liquid fuel and air in said combustion chamber, means for igniting said fuel, said combustion chamber being pro- .vided with side and end walls which cooperate in bending the flame of the ignited fuel back on itself so as to form a zone of intense heat, the sprayed fuel being projected into said zone of intense heat in the combustion chamber, and retained therein until suflicient quantity of oxygen from the air projected into the chamber has united with the combustible of the sprayed fuel to bring about complete combustion.

5. In combination, a heating device including a fire-box, a liquid fuel burning combustion chamber mounted within said fire-box and independent thereof, means forspraying liquid fuel and air in said combustion chamber, means for igniting said pro fuel, said combustion chamber bein vided with suitable confining walls w ereby formation of CO, gas is effected within the combustion chamber.

6. In temperature producing and controlling mechanism, the combination of a liquid fuel burning mechanism, electrically-operated means adapted to stop and start said liquid fuel burning mechanism, means responsive to temperature variations adapted to control said electrically-operated means,

and automatic means independent of said electrically-operated means to stop said liqgiid fuel burning mechanism.'

In temperature producing and controlling mechanism, the combination of a combustion chamber, electricallyoperated means for spraying liquid fuel into said chamber,

" means responsive to temperature variations adapted to control said electrically-operated means, means for igniting said sprayed liquid fuel, and means controlled by an ac- -cumulation of said liquid fuel in the event of failure of said ignition means to stop the operation of said electrically-operated means.

and means responsive to conditions in said chamber arising through failure of said ignition means adapted to discontinue the operation of said electrically-operated means.

9. In temperature producing and controlling mechanism, the combination of a com bustion chamber, a fuel. nozzle associated therewith, liquid fuel and air connections to said fuel nozzle, electrically-operated means for supplying air to said nozzle to thereby atomized fuel, and

combustion chamber, a liquid fuel atomizer in said combustion chamber, means for supplying liquid fuel to said atomizer, a drain connected to said combustion chamber, a receptacle associated with said drain for receiving liquid therethrough from said combustion chamber, electrically-operated means for supplying air to said atomizer, a switch in the circuit of said electrically-operated means, an arm controlling said switch, a spring connected to said arm and operating in one position to hold said switch closed, a connection from said arm to said rece tacle whereby the weight of the accumulatlon of liquid in said receptacle rotates said arm to thereby cause said spring to operate to movesaid arm to open the circuit of said electrically-operated means.

11. In a liquid fuel burning mechanism a" a source of supply or 1i uid fuel atomizer, said liquid fuel, a fuel line from said source of supply to said atomizer, a valve in said line, a float chamber in said line adapted to maintain the liquid at a predetermined level in said chamber, and automatic means adapted to close said valve on an abnormal rise of liquid in said chamber beyond the predetermined level.

12. In temperature producing and controlling mechanism, the combination of a liquid fuel burning apparatus, ignition means therefor comprising a pilot flame and automatic means for momentarily enlarging said. flame.

13. In temperature producing and icontrolling mechanism, the combination of a liquid fuel atomizer, electrically-operated means adapted to actuate said atomizer,

, means for igniting said atomized liquid, and

means responsive to temperature variations arranged to control said electrieally operat ed means and said ignition means.

14. In temperature producing and con-- trolling mechanism, the combination of a liquid fuel atomizer, electrically-operated meansadapted to actuate said atomizer, a pilot flame for igniting said atomized liquid, and means responsive to temperature variations arranged to control said electricallyoperated means'and said pilot flame.

' In temperaturev producing and cont lling mechanism, the combination of a combustion chamber, a liquid fuel atomizer associated with said combustion chamber, means for supplying liquid" fuel to said atomizer, a pilot flame for igniting said automatic means for ated means are started in operation.

to sa d atomizer and t 1'2. In. temperature producing and con-'- trolling mechanism,'the combination of acombustion chamber, a liquid fuel atomizer associated with said combustion chamber, electrically-operated means for suppl ing liquid fuel to said atomizer, a pilot ame in said combustion chamber for igniting said fuel, an automatically-controlled mechanism for first enlarging said pilot flame then starting said electrically-operated means into 0* eration to thereb supply liquid fuel hen again reducing said pilot flame.

18: In temperature producing and controlling mechanism, the combination of a combustion chamber, a liquid fuel atomizer associated with said combustion chamber, electrically-operated. means for supplying liquid fuel to said atomizer, a pilot flame in said combustion chamber for igniting said atomized fuel, means for starting and stopping said electrically-operated means and for momentarily enlarglng said pilot flame both when said electrically-operated means are started into operation and when said meansare stopped.

19. In temperature producing and controlling mechanism, the combination of a combustion chamber, a liquid fuel atomizer associated with said combustion chamber, a pilot flame in said combustion chamber for igniting said atomized fuel, a gas i pe connected to said pilot flame, a norma ly closed valve in said gas pipe, a by-pass around said valve and ermitting a small amount of gas to be supplied to said pilot flame whereby the same burns with a small flame, and automaticall -controlled means for supplying liquid fue to the atomizer and for momentarily opening said valve to thereby enlarge said'pilot flame.

20. In temperature producing and controlling mechanism, the combination of a combustion chamber, a liquid fuel atomizer associatedwith said combustion chamber,

l a pilot flame in said combust on chamber for igniting said liquid fuel, automatically-controlled mechanism for supplying liquid fuel to said atomizer and for momentarily enlarging said pilot flame when said fuel supply means are started into operation, and

means controlled by an accumulation ,of liquid fuel upon failure ofsaid ign i means to stop the supply f' fuel to said atomizer. p

21. In temperature producing and controlling mechanism, the combination of a combustion chamber, a liquid fuel atomizer adjacent to said combustion chamber, a

, boiler associated with said combustion chamber, temperature-controlled means for supplying liquid fuel to said atomizer, and means responsive to boiler conditions for rendering inoperative said temperature-controlled means and for rendering the fuel supply means dependent upon boiler conditions,

-22. In temperature producing and controlling mechanism, the combination of a combustion chamber, a liquid fuel atomizer adjacent to saidcombustion chamber, a boiler associated with said combustion chamber, electrically-operated means for supplying liquid fuel to said atomizer, a thermostat for controlling the circuit of said electrically-operated means, and means associated with said boiler responsive to said boiler conditions for cutting out of circuit said thermostat and for closing an alternative circuit through said electrically-operated means.

23.-In temperature producing and controlling mechanism, the combination of a combustion chamber, a liquid fuel atomizer adjacent to said combustion chamber, a boiler associated with said combustion chamber, electrically-operated means for supplying liquid fuel to said atomizer, a thermostat for controlling said electricall -operated means, and means responsive to oiler conditions independent of said thermostat for 24. In temperature pro cing mechanism, the combination of a liquid fuel atomizer, electrically-operated means adapted to actuate said atomizer, means for igniting said liquid fuel, a boiler or other heat-absorbing medium associated with said atomizer, and means outside of and independent of said heat-absorbing medium responsive to temperature variations arranged to control said electrically-operated means and said ignition means.

Signed by me at Chicago, Illinois, this 14 day of November, 1919.

' ALBERT B. FRENIER.

controllingsaid electricalliy-operated means. 

